Early use of high-dose insulin euglycaemic therapy for verapamil toxicity

A 49-year-old man presented with verapamil toxicity complicated by hypotension and a junctional rhythm, in the context of deliberate self-poisoning with multiple drugs. The patient’s hypotension normalised following the early use of high-dose insulin euglycaemic therapy (HIET), without the need for additional vasopressors; it recurred when HIET was prematurely stopped, and again stabilised when HIET was recommenced. Consideration should be given to the early use of HIET in treating severe calcium channel blocker toxicity, rather than as a last resort after other therapies have failed. (MJA 2009; 191: 350-352)

The patient remained hypotensive (BP, 75/45 mmHg; pulse, 56 beats/min) after intubation, so high-dose insulin euglycaemic therapy (HIET) was commenced at 3.5 hours after presentation. He was given dextrose (50 mL 50% glucose) and a 30 IU short-acting insulin IV bolus (~ 0.5 IU/kg), followed by a further bolus of 50 mL 50% glucose and a short-acting insulin IV infusion (30 IU/h) (Box 1). His BP improved to 110/70 mmHg at 4 hours, with a pulse of 82 beats/min and sinus rhythm on ECG, and he remained stable during transfer to the intensive care unit (ICU).

HIET was continued and the patient remained haemodynamically stable. Adrenaline and noradrenaline were weaned off (at 17.5 hours and 23.5 hours, respectively), despite the propofol infusion rate being increased to 500 mg/h at 18.5 hours. Once sedation was withdrawn, the patient was extubated at 26.5 hours. Insulin was weaned over 5 h and discontinued at 30.5 hours; dextrose was stopped 1 h later. The patient was transferred to the observation ward and discharged well later that day, after psychiatric clearance.

During treatment with HIET, the patient’s blood glucose levels were checked hourly and ranged from 6.6 mmol/L to 13.2 mmol/L (RR, 3.5–5.5 mmol/L). He received about 25 g/h of dextrose (mostly as 50% dextrose infusions). Potassium and magnesium levels were also serially monitored; the minimum potassium level was 2.7 mmol/L (RR, 3.5–5.0 mmol/L) at 8.75 hours, and the magnesium level troughed at 0.5 mmol/L (RR, 0.75–1.05 mmol/L) at 15 hours. These were corrected with a total of 200 mmol of potassium chloride and 20 mmol magnesium chloride.

Discussion

HIET is an increasingly accepted therapy for calcium channel blocker (CCB) toxicity, but reports of its use are limited and it remains controversial. Indeed, the scarcity of severe CCB poisoning cases means that a randomised controlled trial of HIET may not be feasible.1 Treating clinicians who seek advice from clinical toxicologists are often hesitant about the high doses required and the potential for adverse effects. Such hesitancy is potentially harmful, as a hypotensive patient with a CCB overdose who otherwise appears well is at risk of abrupt lethal cardiovascular collapse.1 HIET is traditionally recommended after other therapies have failed.2,3 This case report aims to raise awareness of HIET for the treatment of CCB toxicity and supports its early use, rather than as a last resort.4

Less well known are the metabolic effects of CCBs such as verapamil. Under the stress of the drug-induced shock state, the cardiac myocytes shift from using free fatty acids, their favoured “resting state” energy substrate, to carbohydrates.3,4 CCB toxicity also impairs the uptake of glucose and free fatty acids by cardiac myocytes3,4 and inhibits calcium-dependent mitochondrial activity required for glucose catabolism.3,4 Furthermore, insulin release is dependent on calcium influx into islet beta cells through L-type calcium channels.3,4 Thus, CCB toxicity can cause hypoinsulinaemia,3,4 which, in conjunction with CCB-induced insulin resistance, may lead to hyperglycaemia and a ketoacidotic state.6

Atropine, calcium boluses and infusions, glucagon, inotropes, vasopressors, and cardiac pacing have all been advocated for managing CCB toxicity, despite questionable efficacy.3,4,7-9 For instance, the evidence for glucagon is limited to small, non-blinded animal studies where no survival benefit or improvement in mean arterial pressure was shown, although heart rate improved in some cases.7 Rarely, heroic measures such as extracorporeal circulatory support and intra-aortic balloon counterpulsation have been successfully employed.5,10

HIET was first used to treat verapamil toxicity in humans in 1993, with a favourable outcome.6 Since then, in addition to animal studies, there have been nearly 70 cases reporting the beneficial use of HIET in humans, with an overall survival rate of 85%.8 However, to our knowledge, use of HIET in humans before the administration of glucagon or vasopressors has only been reported once.6 There have been some reports of HIET failure in treating CCB toxicity, although the dosing of insulin was low or uncertain, or it was used late.6,8 Early use of HIET may be more effective than HIET rescue therapy, as CCB-induced insulin resistance is greatest in the first 24 hours2 and the maximal haemodynamic benefit of HIET may not occur immediately.6

HIET may be best used adjunctively with other measures such as catecholamines, for two reasons. First, insulin-mediated inotropy is not catecholamine-mediated, and is not affected by β blockers.3 Second, although insulin appears to improve myocardial contractility, it has no chronotropic effect and may cause vasodilation.3,8

HIET is safe, and adverse events are predictable, uncommon, and easily managed.2,8 The maximum safe dose of insulin is unknown, but loading doses of 0.5–1.0 IU/kg followed by infusions of 0.1–2.5 IU/kg/h are typically used.8 Interestingly, neither the inadvertent administration of a 1000 IU insulin loading dose for verapamil toxicity13 nor treatment of toxic cardiogenic shock for 2 days with a 6 IU/kg/h insulin infusion had any adverse effects.14 Adverse effects of HIET include hypoglycaemia, hypokalaemia, hypomagnesaemia, and hypophosphataemia.2,6,8 Although these are rarely clinically significant, they necessitate careful monitoring. Hypoglycaemia (blood glucose < 3.3 mmol/L) occurred in 16% of 55 published cases,8 and no cases of hypoglycaemia within 24 hours of CCB overdose were noted in Greene and colleagues’ series of seven cases.2 Greene et al also reported a mean dextrose requirement of 0.05 g/kg/h (range, 0–0.17 g/kg/h), although the mean blood glucose level exceeded the euglycaemic range.2 Some cases of severe CCB toxicity in patients presenting with hyperglycaemia do not require any additional glucose administration despite high-dose insulin therapy,15 and hypoglycaemia may be more likely in milder cases without marked hypotension.8 In addition, hypokalaemia (potassium < 3.5 mmol/L) was noted in only two patients in Greene et al’s small series, with a minimum potassium level of 2.8 mmol/L.2 Excessive correction of hypokalaemia should be avoided, because it reflects the intracellular shift of potassium from the extracellular compartment due to the action of insulin, rather than a potassium-depleted state.4 Interestingly, hypokalaemia in HIET may augment myocardial contractility by enhancing calcium entry during systole, and increased intracellular potassium may have a membrane-stabilising effect in excitable cells.4,6

In conclusion, we advocate consideration of the early use of HIET (as detailed in Box 2) for the prevention and treatment of life-threatening complications from potentially lethal CCB overdoses. HIET is safe, inexpensive and freely available, and suitable for use even in remote settings before transfer to a referral centre.

1 Early changes in the patient’s systolic blood pressure (SBP) and heart rate, relative to treatment with high-dose insulin and adrenaline infusions

Following administration of a 0.5 IU/kg short-acting insulin bolus 3.5 hours after presentation, a short-acting insulin intravenous infusion (0.5 IU/kg/h) was commenced (black line), and the patient’s blood pressure improved. The infusion was abruptly discontinued 2 hours later and the patient again became hypotensive. This resolved following commencement of an adrenaline infusion (20 μg/min)
(grey arrow), and the insulin infusion (0.5 IU/kg/h) was restarted 8.5 hours after presentation (black arrow).

2 Recommended high-dose insulin euglycaemic therapy protocol,3,4,9 based on the clinical experience of the Western Australian Toxicology Service, published case reports, reviews and animal studies

Therapy is weaned after the withdrawal of other vasopressors, as cardiotoxicity resolves. Dextrose may be required after cessation
of insulin.

IV = intravenous. BP = blood pressure. * The maximum safe and effective rate of infusion is unknown but may be even higher than 5 IU/kg/h. In animal studies, insulin infusions as high as 10 IU/kg/h have been safely used.11